Method for controlling free lime content of clinker

Provided is a method for controlling a free lime content of a clinker by regulating the free lime content. Here the amount of sulfur trioxide resulting from fuel and the used amount of a fluorine-based mineralizer are regulated using the following Formulas (1) to (3), thereby controlling the free lime content (f.CaO) of the clinker. f.CaO=0.29×e(0.65×A)(A=a×SO3+b)  (1) a=0.0001×F+9.2×t−0.18×HM−9.2  (2) b=−0.0005×F−32.8×t−2.9×HM+28.4  (3) SO3 is an amount of sulfur trioxide in the clinker; a is a coefficient satisfying Formula (2); b is a coefficient satisfying Formula (3); F is an amount of fluorine in the clinker; when a burning temperature is X° C., t=X/1450; and HM is a hydraulic modulus.

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Description
TECHNICAL FIELD

The present invention relates to a method for controlling a free lime content of a clinker in a production method of cement so as to suppress cement quality fluctuation caused by the fluctuation of the free lime content.

Priority is claimed on Japanese Patent Application No. 2012-077525, filed Mar. 29, 2012, the content of which is incorporated herein by reference.

BACKGROUND ART

In cement plants, a mixed and ground substance consisting of limestone, clay, silica stone, iron ore, and the like is burned at a high temperature in an SP kiln or in an NSP kiln, thereby producing a hydraulic clinker. The free lime content of the clinker exerts an influence on physical properties of cement, and accordingly, the factories produce the clinker while controlling the free lime content to fall within a certain range.

Conventionally, as the method for controlling the free lime content, a method of varying the mixing ratio of respective raw materials (adjusting chemical components of a mixture of raw materials), the amount of raw materials put into the kiln, the rotation speed of the kiln, the length of flames of a burner, the amount of kiln exhaust gas to be aspirated, and the like or a method of using a mineralizer is used.

For example, in the production method disclosed in PTL 1, the free lime content of the clinker and the like is controlled to be equal to or smaller than 0.5% by mass. Moreover, in the method disclosed in PTL 2, the free lime content and the fluorine content of cement are controlled such that they satisfy a certain relational expression. Furthermore, PTL 3 discloses a production method which makes it possible to decrease the cement clinker burning temperature without increasing the amount of fluorine by causing the burned clinker to contain one or more elements selected from a group consisting of fluorine, sulfur, chlorine, and bromine as well as one or more metal elements selected from a group consisting of group 3 to group 12 elements.

However, there is a limit to control the free lime content by the above methods, and in the current situation, a great fluctuation of the free lime content is unavoidable. When the free lime content fluctuates, the basic physical properties of cement (concrete), such as setting properties, strength, and fluidity, are influenced.

CITATION LIST Patent Literature

[PTL 1] Japanese Unexamined Patent Application, First Publication No. 2008-285370

[PTL 2] Japanese Unexamined Patent Application, First Publication No. 2001-130932

[PTL 3] Japanese Unexamined Patent Application, First Publication No. 2011-207752

SUMMARY OF INVENTION Technical Problem

The present invention provides a method for suppressing cement quality fluctuation caused by the fluctuation of the free lime content by controlling the free lime content of the clinker to fall within a certain range in a cement production process.

Solution to Problem

According to the present invention, there is provided a method for controlling a free lime content that is constituted as below.

[1] A method for controlling a free lime content of a cement clinker, includes regulating the free lime content (f.CaO) in the cement clinker using Formulas (1) to (3).
f.CaO=0.29×e(0.65×A)(A=a×SO3+b)  (1)
a=0.0001×F+9.2×t−0.18HM−9.2  (2)
b=−0.0005×F−32.8×t+2.9×HM+28.4  (3)

wherein in Formula (1), f.CaO is a free lime content (wt %),

SO3 is an amount (wt %) of sulfur trioxide in the cement clinker,

a is a coefficient satisfying Formula (2),

b is a coefficient satisfying Formula (3),

F is an amount (mg/kg) of fluorine in the cement clinker,

t is a coefficient determined based on a temperature of 1450° C. (when a burning temperature is X° C., t=X/1450), and

HM is a hydraulic modulus.

[2] The method for controlling a free lime content of a cement clinker according to [1], the method may further include adjusting an additive amount of fluorite or fluorine-containing waste that is a fluorine source in the cement clinker and used as a mineralizer, and an used amount of fuel or an additive amount of waste gypsum as an SO3 source in the cement clinker to control the free lime content (f.CaO) using the Formulas (1) to (3).

According to the control method of the present invention, it is possible to control the free lime content (f.CaO) of the clinker, by adjusting the used amount of fuel or the additive amount of waste gypsum as an SO3 source in the clinker, and by adjusting the additive amount of fluorite or fluorine-containing waste that is a fluorine source in the clinker and used as a mineralizer using the Formula (1).

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a graph showing the correspondence between a calculated value of a free lime content and an actual measured value of the free lime content.

FIG. 2 is a graph showing the relationship between the SO3 amount and the fluorine amount at a burning temperature of 1450° C.

FIG. 3 is a graph showing the relationship between the SO3 amount and the fluorine amount at a burning temperature of 1350° C.

FIG. 4 is a graph showing the relationship between the SO3 amount and the fluorine amount at a burning temperature of 1300° C.

 DESCRIPTION OF EMBODIMENTS

Hereinafter, the control method of the present invention will be described in detail based on embodiments.

The control method of the present invention is a method for controlling a free lime content of a cement clinker, in which the free lime content (f.CaO) of the clinker is regulated using Formulas (1) to (3).
f.CaO=0.29×e(0.65×A)(A=a×SO3+b)  (1)
a=0.0001×F+9.2×t−0.18×HM−9.2  (2)
b=−0.0005×F−32.8×t−2.9×HM+28.4  (3)

In Formula (1), f.CaO is a free lime content (wt %); SO3 is the amount (wt %) of sulfur trioxide in the clinker; a is a coefficient satisfying Formula (2); b is a coefficient satisfying Formula (3); F is the amount (mg/kg) of fluorine in the clinker; t is a coefficient determined based on a temperature f 1450° C. (when a burning temperature is X° C., t=X/1450); and HM is a hydraulic modulus.

Most of SO3, which represents an amount of sulfur trioxide in the clinker, results from fuel for burning. Moreover, the SO3 amount in the clinker is adjusted by intermixing waste gypsum board powder with fuel or by putting the waste gypsum board powder into a kiln from the kiln outlet part. The used amount of fuel or the amount of waste gypsum put into the kiln is adjusted, it is possible to control the SO3 amount represented using Formula (1).

Moreover, a mineralizer is added to the raw materials of the clinker. Fluorite, fluorine-containing waste (sludge), and the like are used as the mineralizer. Fluorine contained in the clinker mainly results from the mineralizer. Accordingly, for example, by adjusting the additive amount of mineralizer, it is possible to regulate the coefficients a and b of Formulas (2) and (3) including the fluorine amount F and to finally control the SO3 amount in the clinker represented by Formula (1).

The hydraulic modulus HM is an index represented by HM=CaO/(SiO2+Al2O3+Fe2O3). The greater the HM is, the amount of calcium oxide or alite in the clinker increases. As a result, burning reactivity decreases, hence the amount of free lime content increases. Generally, the hydraulic modulus HM of the raw material of the clinker is 1.90 to 2.30.

Furthermore, Formula (1) is satisfied when the fluorine amount F in the clinker is equal to or greater than 300 mg/kg. If the fluorine amount F in the clinker is smaller than this, the correlation between fluorine and SO3 tends to be weakened, and the free lime content (f.CaO) of the clinker tends to increase greater than the value represented by Formula (1).

EXAMPLES

Examples of the present invention will be described below.

The SO3 amount in the clinker was measured according to JIS R 5202:2010 “Methods for chemical analysis of cement”. The fluorine amount in the clinker was measured by X-ray fluorescence analysis (powder briquette method or bead method).

The free lime content (f.CaO) of the clinker was measured according to JCAS I-01:1997 “Quantification of free calcium oxide”.

The burning temperature coefficient t is a coefficient determined based on a temperature of 1450° C. When the burning temperature is 1350° C., t=1350/1450=0.93, and when the burning temperature is 1450° C., t=1450/1450=1.00.

Example 1

The SO3 amount, fluorine amount, and free lime content (f.CaO) of the produced dement clinker were measured. The results are shown in Table 1 together with the hydraulic modulus HM and the burning temperature coefficient t. Moreover, the free lime content (estimated f.CaO), which is calculated by plugging the hydraulic modulus of the raw material, the burning temperature coefficient, the measured SO3 amount, and the fluorine amount into Formula (1), is also shown in Table 1. In addition, the relationship between the free lime content (estimated f.CaO) based on Formula (1) and the actual measured free lime content (f.CaO) is shown in FIG. 1.

As shown in Table 1, a difference between the free lime content (f.CaO) based on Formula (1) and the actual measured free lime content (f.CaO) is small and within a narrow range as shown in FIG. 1. This shows that Formula (1) showing the free lime content (f.CaO) of the clinker is highly reliable, and accordingly, it is possible to reliably control the free lime content (f.CaO) of the clinker based on Formula (1).

Example 2

FIG. 2 and FIG. 3 show the relationship between the SO3 amount and the fluorine amount that make the free lime content (f.CaO) at each burning temperature fall within a range of 0.5<f.CaO<1.0 based on Formula (1) when each of the raw materials of the clinker having the hydraulic modulus HM of 1.9, 2.1, and 2.3 is burned at 1300° C., 1350° C., and 1450° C. respectively. In the drawings, the shaded area is in a range of 0.5<f.CaO<1.0. By adjusting the SO3 amount and the fluorine amount, it is possible to control the free lime content to fall within a range of 0.5<f.CaO<1.0.

TABLE 1 SO3 F t HM f.CaO Estimated f.CaO Example 1 1.83 1160 1.00 1.89 0.18 0.30 Example 2 0.43 1015 1.00 1.89 0.21 0.38 Example 3 0.84 2455 1.00 2.31 0.26 0.50 Example 4 2.64 2610 1.00 2.31 0.26 0.42 Example 5 0.41  305 1.00 1.88 0.33 0.46 Example 6 1.83 1150 0.93 1.90 0.36 0.64 Example 7 2.11  340 1.00 1.89 0.38 0.35 Example 8 2.00 5000 0.93 2.10 0.39 0.36 Example 9 1.62 2535 1.00 2.31 0.39 0.46 Example 10 3.05 2370 0.93 2.30 0.41 0.51 Example 11 2.09  340 0.93 1.91 0.43 0.66 Example 12 1.72 1450 1.00 2.30 0.46 0.58 Example 13 2.62 1605 1.00 2.30 0.46 0.49 Example 14 0.84 1625 1.00 2.30 0.49 0.63 Example 15 2.01 2670 0.93 2.30 0.49 0.81 Example 16 2.00 2440 0.93 2.10 0.50 0.61 Example 17 0.50 5000 0.93 2.10 0.50 0.58 Example 18 2.00 5000 0.90 2.10 0.55 0.50 Example 19 2.00 1340 0.93 2.10 0.56 0.77 Example 20 1.73  645 1.00 2.31 0.56 0.70 Example 21 0.43 1020 0.93 1.90 0.56 1.41 Example 22 2.00 2700 0.90 2.10 0.63 0.80 Example 23 0.88  595 1.00 2.31 0.66 0.84 Example 24 3.15 2740 0.90 2.31 0.71 0.50 Example 25 2.72  695 1.00 2.30 0.74 0.56 Example 26 1.12 2780 0.93 2.31 0.82 1.23 Example 27 3.05 1580 0.93 2.31 0.84 0.57 Example 28 0.50 5000 0.90 2.10 0.86 1.10 Example 29 1.10 1595 0.93 2.31 0.87 1.71 Example 30 2.07 1565 0.93 2.31 0.87 1.00 Example 31 2.00 1390 0.90 2.10 1.14 1.06 Example 32 2.12 2700 0.90 2.30 1.20 1.03 Example 33 0.50  620 0.93 2.10 1.25 2.21 Example 34 2.00  655 0.93 2.31 1.63 1.25 Example 35 1.10  675 0.93 2.30 1.86 2.17 Example 36 0.50 2310 0.90 2.10 1.95 2.49 Example 37 1.15 2650 0.90 2.31 2.41 2.09 Example 38 1.15 1635 0.90 2.31 3.39 2.71 Example 39 0.50 1195 0.90 2.10 3.52 3.50 Example 40 1.16  670 0.90 2.30 4.44 3.45 Example 41 0.50  640 0.90 2.10 4.89 4.15 Note: SO3 is an SO3 amount (wt %) in the clinker; F is a fluorine amount (mg/kg) in the clinker; t is a coefficient determined based on a burning temperature (1.00 = 1450/1450, 0.93 = 1350/1450); f.CaO is an actual measured value (wt %); and Estimated f.CaO is a value calculated (wt %) based on Formula (1).

INDUSTRIAL APPLICABILITY

The present invention can be applied to a method for controlling the free lime content (f.CaO) of the clinker by adjusting the used amount of fuel or the additive amount of waste gypsum as an SO3 source in the clinker, and adjusting the additive amount of fluorite or fluorine-containing waste that is a fluorine source in the clinker and used as a mineralizer using the Formula (1).

Claims

1. A method for controlling a free lime content of a cement clinker, comprising:

adding fluorite or fluorine-containing waste that is a fluorine source in the cement clinker and used as a mineralizer to raw materials of the cement clinker,
intermixing a waste gypsum board powder with fuel or putting the waste gypsum board powder into a kiln from the kiln outlet part as an SO3 source in the cement clinker,
burning the raw materials of the cement clinker added the fluorite or the fluorine-containing waste in the kiln to produce the cement clinker,
calculating the free lime content (f.CaO) of the cement clinker according to Formulas (1) to (3),
adjusting an additive amount of fluorite or fluorine-containing waste and an used amount of fuel or an additive amount of waste gypsum according to the calculated free lime content to control the free lime content (f.CaO) so as to fall within a range of 0.5<f.CaO<1.0, f.CaO=0.29×e(0.65×A)(A=a×SO3 +b)  (1) a=0.0001×F+9.2×t−0.18×HM−9.2  (2) b=−0.0005×F−32.8×t+2.9HM+28.4  (3)
in Formula (1), f.CaO is a free lime content (wt %),
SO3 is an amount (wt %) of sulfur trioxide in the cement clinker,
a is a coefficient satisfying Formula (2),
b is a coefficient satisfying Formula (3),
F is an amount (mg/kg) of fluorine in the cement clinker,
t is a coefficient determined based on a temperature of 1450° C. (when a burning temperature is X° C., t=X/1450), and
HM is a hydraulic modulus.

2. The method for controlling a free lime content of a cement clinker according to claim 1,

wherein the amount of fluorine in the cement clinker is equal to or greater than 300 mg/kg.
Referenced Cited
U.S. Patent Documents
4716532 December 29, 1987 Benoit et al.
5584926 December 17, 1996 Borgholm
6599123 July 29, 2003 Ramirez-Tobias
20070193477 August 23, 2007 Sawaki et al.
20070266903 November 22, 2007 Gartner et al.
Foreign Patent Documents
1098076 February 1995 CN
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Other references
  • H.F.W. Taylor “Cement Chemistry 2nd edition”, 1997, pp. 72-74 and a cover page.
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Patent History
Patent number: 9598312
Type: Grant
Filed: Mar 8, 2013
Date of Patent: Mar 21, 2017
Patent Publication Number: 20150321956
Assignee: MITSUBISHI MATERIALS CORPORATION (Tokyo)
Inventors: Yuuki Ninomiya (Chichibu-gun), Hisanobu Tanaka (Chichibu-gun), Makio Yamashita (Chichibu-gun), Yoichiro Nakanishi (Tokyo)
Primary Examiner: Kaj K Olsen
Assistant Examiner: Karam Hijji
Application Number: 14/388,513
Classifications
Current U.S. Class: Portland Type Cement (106/713)
International Classification: C04B 7/44 (20060101); C04B 7/36 (20060101); C04B 7/42 (20060101);